KR100997550B1 - metal fuel cell - Google Patents

Abstract

The present invention relates to a metal fuel cell having a new structure that can not only firmly install the negative electrode terminal, but also continuously supply oxygen and electrolyte, and effectively remove magnesium hydroxide generated during power generation to increase power generation efficiency.

In the metal fuel cell according to the present invention, since the negative electrode terminal 30 extends to the outside of the cell body 10 while being inserted into the insertion hole 21 formed in the metal electrode body 20, the negative electrode terminal 30 is firmly secured. There is an advantage that can be fixed. In addition, an air supply port 13b, an electrolyte supply port 13c, and an outlet port 14a are formed in the cell body 10, respectively, and by controlling the supply and discharge of the electrolyte solution using the control unit 90, By supplying air and electrolyte, and by discharging magnesium hydroxide which is a by-product of power generation, there is an advantage to increase the power generation efficiency.

Fuel cells, metals, magnesium, air cells, electrolytes,

Description

Metal fuel cell

The present invention relates to a metal fuel cell having a new structure that can not only firmly install the negative electrode terminal, but also continuously supply oxygen and electrolyte, and effectively remove magnesium hydroxide generated during power generation to increase power generation efficiency.

In general, the metal fuel cell for producing electricity using the metal electrode body, as shown in Figure 1, the cell body 10 is injected into the electrolyte solution therein; A metal electrode body 20 installed inside the cell body 10; The air electrode 40 is disposed on the circumference of the cell body 10 so as to be spaced apart from the metal electrode body 20.

The cell body 10 is formed in a cylindrical shape formed with a plurality of through holes 11 on the circumferential surface. In addition, the electrolyte solution is mainly used aqueous sodium chloride (NaCl).

The metal electrode body 20 is manufactured by sintering a mixture of magnesium, aluminum, and zinc, and fixed to the inside of the cell body 10 so as to be immersed in the electrolyte, and reacted with a hydroxyl group in the electrolyte to oxidize to an oxide. In this process, electrons and hydrogen are generated to act as a cathode for generating electrons.

The air electrode 40 is composed of a carbon sheet 41, a conductor, and a metal mesh 42 made of stainless material provided on an outer surface of the carbon sheet 41 to support the carbon sheet 41, It is coupled to surround the outer circumferential surface of the cell body 10 to block the through-hole 11 so that the electrolyte does not leak and at the same time the inner surface is in contact with the electrolyte, the metal electrode body 20 It functions as an anode that receives the electrons generated by it. At this time, the metal mesh 42 is a function of improving the electrical conductivity of the carbon sheet 41 while at the same time weaving very thin wire tightly to support the carbon sheet 41.

The negative electrode terminal (not shown) is connected to the metal electrode body (20), and the positive electrode terminal (not shown) is connected to the air electrode (40).

Therefore, when the cathode terminal and the anode terminal are electrically connected to each other, electrons and hydrogen are generated in the metal electrode body 20, and the generated electrons are externally connected to the metal electrode body 20 and the air electrode 40. It is delivered to the air electrode 40 along the circuit, and combines with hydrogen and oxygen in the electrolyte to produce a reduction reaction to produce water. In addition, the electrochemical reaction is continuously repeated to produce electricity.

By the way, such a metal fuel cell should be connected to the negative electrode terminal to the metal electrode body 20, it is very cumbersome to connect and fix the negative electrode terminal to the metal electrode body 20, the fixing portion of the negative electrode terminal is structurally weak There was a problem of becoming.

In addition, when the power is continuously used, the magnesium hydroxide is not generated by the reaction of the magnesium and the electrolyte solution, the magnesium hydroxide remains in the interior of the electrolyte solution to reduce the electrochemical reaction efficiency of the electrolyte solution to reduce the power generation efficiency There was a problem.

In addition, in the metal fuel cell, a sufficient amount of oxygen is supplied from the air electrode 40 to cause a reduction reaction by electrons so that the reaction proceeds actively. However, at present, there is no method for supplying a sufficient amount of air into the container, and there is a problem in that there is a limit in improving the efficiency of the metal fuel cell.

The present invention is to solve the above problems, it is possible to install a negative electrode terminal, as well as to continuously supply oxygen and electrolyte, and to effectively remove the magnesium hydroxide generated during power generation to increase the power generation efficiency The object is to provide a metal fuel cell of the structure.

The present invention for achieving the above object, Cell body 10 is injected into the electrolyte solution; A metal electrode body 20 installed inside the cell body 10; A negative electrode terminal 30 connected to the metal electrode body 20; An air electrode 40 installed in the cell body 10 so as to be spaced apart from the metal electrode body 20; In the metal fuel cell including the positive electrode terminal 50 connected to the air electrode 40, the insertion hole 21 in the longitudinal direction is formed in the metal electrode body 20, the negative electrode terminal 30 once Inserted and fixed in the insertion hole 21, the other end is provided with a metal fuel cell, characterized in that extending to the outside of the cell body (10).

According to another feature of the invention, the negative electrode terminal 30 is a conductor and is formed by winding a metal plate having elasticity and a plurality of protrusions 31a are formed on the outer circumferential surface of the insertion hole of the metal electrode body 20 ( Provided is a metal fuel cell comprising a condenser portion 31 inserted into the 21 and a terminal portion 32 coupled to the cell body 10 and connected to an end of the condenser portion 31. .

According to another feature of the present invention, an air supply port 13b for supplying air and an electrolyte supply port 13c for supplying an electrolyte are formed at an upper end of the cell body 10, and the cell body 10 is formed. The discharge port 14a is formed at the lower end of the electrolyte supply means 60 connected to the electrolyte supply port 13c and the air supply means 70 connected to the air supply port 13b is further provided. A metal fuel cell is provided.

According to another feature of the invention, inside the cell body 10, one end is connected to the air supply port 13b and the other end extends between the air electrode 40 and the metal electrode body 20. Provided is a metal fuel cell, characterized in that the extension tube 71 is further provided.

According to another feature of the invention, the electrolytic solution supply port 13c and the discharge port (14a) is provided with an electronic control valve (13d, 14b), respectively, is provided in the cell body (10) inside the cell body (10) And a control unit 90 for controlling the electronic control valves 13d and 14b according to the signal of the water level sensor 80 and the water level sensor 80 for detecting the level of the electrolyte solution. A metal fuel cell is provided.

In the metal fuel cell according to the present invention, since the negative electrode terminal 30 extends to the outside of the cell body 10 while being inserted into the insertion hole 21 formed in the metal electrode body 20, the negative electrode terminal 30 is firmly secured. There is an advantage that can be fixed. In addition, an air supply port 13b, an electrolyte supply port 13c, and an outlet port 14a are formed in the cell body 10, respectively, and by controlling the supply and discharge of the electrolyte solution using the control unit 90, By supplying air and electrolyte, and by discharging magnesium hydroxide which is a by-product of power generation, there is an advantage to increase the power generation efficiency. In addition, there is an advantage that the supply efficiency of oxygen can be improved by supplying air directly into the electrolyte using the extension pipe 71.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

2 to 6, the metal fuel cell according to the present invention includes a cell body 10 into which an electrolyte is injected; A metal electrode body 20 installed inside the cell body 10; A negative electrode terminal 30 connected to the metal electrode body 20; An air electrode 40 installed in the cell body 10 so as to be spaced apart from the metal electrode body 20; It is the same as the conventional one including the positive terminal 50 connected to the air electrode 40.

In addition, according to the present invention, the metal electrode body 20 is formed with an insertion hole 21 in a longitudinal direction, and the cathode terminal 30 has one end fixedly inserted into the insertion hole 21 and the other end of the cell. An electrolyte supply means 60 and an air supply means 70 extending out of the body 10 and connected to the cell body 10; A water level sensor 80 provided in the cell body 10; The control unit 90 connected to the water level sensor 80 is further provided.

In detail, the cell body 10 has an opening 12a through which the air electrode 40 is coupled to a circumference thereof, the body body 12 having a cylindrical shape having an upper and lower end open, and the body body ( An upper cover 13 provided at an upper end of the 12; A lower cover 14 coupled to the lower end of the body body 12 and a bracket 15 installed inside the body body 12 to support the metal electrode body 20. At this time, the body body 12 has a high corrosion resistance, and is composed of a hard synthetic resin, which is a non-conductor, the exhaust port 12b is formed at a position higher than the level of the electrolyte injected into the upper side, and is generated during power generation. Hydrogen gas is configured to be exhausted to the outside through the exhaust port (12b). In addition, a through hole 13a through which the negative electrode terminal 30 penetrates is formed in the center of the upper cover 13. In addition, an air supply port 13b and an electrolyte supply port 13c to which the air supply means 70 and the electrolyte supply means 60 are connected are formed at both sides of the upper cover 13, respectively, and the lower cover 14 is provided. ) Is formed with a discharge port (14a) for discharging the electrolyte injected into the body body 12, the electrolytic solution supply port 13c and the discharge port (14a) is provided with an electronic control valve (13d, 14b), respectively.

The metal electrode body 20 is manufactured by sintering a mixture of magnesium, aluminum, and zinc, and inserted into the cell body 10 so as to be placed on the bracket 15 of the cell body 10. Supported by). In this case, the insertion hole 21 is formed to penetrate the upper and lower surfaces of the metal electrode body 20 in a circular shape.

The negative electrode terminal 30 has a capacitor portion 31 inserted into the insertion hole 21 of the metal electrode body 20 and a terminal portion coupled to the cover and connected to an end of the condenser portion 31. 32). The condenser unit 31 is formed of a conductor and an elastic metal plate wound in a cylindrical shape, and a plurality of protrusions 31a are formed on the outer circumferential surface, and the protrusion 31a is in close contact with the inner circumferential surface of the insertion hole 21 and at the same time. It is installed to protrude to the upper end of the metal electrode body 20. At this time, the condenser part 31 is configured such that both ends of the metal plates constituting the condenser part 31 are spaced apart from each other by a predetermined distance (L), so that the diameter of the condenser part 31 can be elastically stretched and condensed. When the part 31 is inserted into the insertion hole 21, the protrusion 31a is completely fixed to the insertion hole 21 by the self-elasticity of the condenser 31. The terminal portion 32 is inserted into the through hole 13a formed in the upper cover 13, and is fixed to the upper end of the condenser portion 31 by pins not shown.

The air electrode 40 has a sheet shape, and a circumferential surface of the air electrode 40 is tightly fixed to the opening 12a of the body main body 12. The electrolyte injected into the cell body 10 flows to the outside. And a catalytic function of allowing hydroxyl and oxygen to react with each other by electrons supplied through the anode terminal 50. In this case, as shown in FIG. 6, the air electrode 40 is embedded in a carbon sheet 31 made of carbon in a sheet shape, and an outer surface of the carbon sheet 31 so as to provide electricity to the carbon sheet 31. It is made of a stainless metal mesh 42 to improve the conductivity and at the same time to reinforce the carbon sheet 31, the outside is configured to improve the conductivity is coated with a conductive material. In addition, the carbon sheet 31 is formed with a plurality of vent holes 41a penetrating the inner and outer sides. The vent hole 41a is configured to have a diameter small enough to prevent the electrolyte injected into the cell body 10 from leaking to the outside, and the inner diameter of the vent hole 41a is wider from the inner side to the outer side of the carbon sheet 31. The large diameter portion 41b is formed. The large diameter portion 41b is formed deeper than the depth in which the stainless metal mesh 42 is embedded, so that the air vent 41a is not blocked by the stainless metal mesh 42. That is, while the vent hole 41a is very small in diameter, the cross section of the metal mesh 42 constituting the metal mesh 42 is larger than the vent hole 41a so that the vent hole 41a is formed by the metal mesh 42. ), The large diameter portion (41b) is provided on the outside of the vent hole (41a), it is possible to prevent the vent hole (41a) is blocked by the metal mesh 42.

The anode terminal 50 is made of a long rod-shaped conductor in the vertical direction, the lower end is fixed to the stainless steel mesh 42 in contact with the outer peripheral surface of the air electrode 40, the middle portion to the pin 51 It is fixed to the outer surface of the body body 12 by.

The electrolyte supply means 60 is composed of a pump 61 connected to the electrolyte supply port 13c and a storage tank 62 connected to the pump 61 and stored in the electrolyte solution. The electrolyte is supplied to the inside of the cell body 10 and the flow of the electrolyte supplied into the cell body 10 is controlled by turning on and off the electronic control valve 13d provided in the electrolyte supply port 13c. can do.

The air supply means 70 is an air compressor connected to the air supply port 13b and continuously supplies air of a constant pressure into the cell body 10 through the air supply port 13b. At this time, one end of the cell body 10 is connected to the air supply port 13b and the other end is further provided with an extension tube 71 extending between the air electrode 40 and the metal electrode body 20. . That is, when air is simply injected into the upper surface of the electrolyte, oxygen in the air is not supplied to the electrolyte well, so that the air electrode 40 and the metal electrode body 20 which are immersed in the electrolyte by using the extension tube 71. The air is supplied directly between) so that oxygen in the air can be smoothly supplied to the electrolyte.

The level sensor 80 is provided on the top of the body body 12 to monitor the level of the electrolyte injected into the body body 12, the level of the electrolyte is the top of the metal electrode body 20 When it is lower than the fully locked state, it outputs a signal.

The control unit 90 is provided with a time table that records timings for opening and closing each of the solenoid control valves 13d and 14b, and opens and closes the solenoid control valves 13d and 14b according to the input timetable. The electrolyte is injected into the body 10, and the electrolyte inside the cell body 10 is controlled to be discharged through the discharge port 14a. In addition, the control unit 90 detects the signal of the water level sensor 80, when the level of the electrolyte solution inside the cell body 10 is lower than the reference, when the signal is output from the water level sensor 80, the cell The electronic control valve 14b provided in the electrolyte injection port is opened until the electrolyte level in the body 10 becomes higher than the reference level, thereby replenishing the electrolyte.

Reference numeral 12c, which has not been described, shows an exhaust pipe coupled to the exhaust port 12b.

Therefore, when the electronic control valves 13d and 14b are opened by the control of the control unit 90, the air supply means 70 and the electrolyte supply means 60 enter the cell body 10. Electrolyte and air are supplied. Accordingly, the metal electrode body 20 and the air electrode 40 continuously generate an oxidation reaction and a reduction reaction to generate electricity, and the generated hydrogen gas is exhaust gas 12b. Is discharged to outside. In addition, since magnesium hydroxide generated by the oxidation reaction of magnesium sinks downward due to a higher specific gravity than the electrolyte, the electrolytic solution containing magnesium hydroxide is discharged by opening the electronic control valve 14b provided in the outlet 14a. At the same time, by additionally supplying air and electrolyte using the air supply means 70 and the electrolyte supply means 60, the level of the electrolyte in the cell body 10 is constantly adjusted. At this time, when the electrolyte is excessively discharged and the level of the electrolyte in the cell body 10 is lowered, the control unit 90 opens the electronic control valve 13d to supply additional electrolyte, thereby lowering the level of the electrolyte. To prevent them.

The metal fuel cell configured as described above extends to the outside of the cell body 10 in the state where the negative electrode terminal 30 is inserted into the insertion hole 21 formed in the metal electrode body 20, and thus, the negative electrode terminal 30. The installation is very easy, and the structural strength of the negative electrode terminal 30 has the advantage of high.

The negative electrode terminal 30 includes a condenser portion 31 formed by rolling a resilient metal plate in a cylindrical shape, and a terminal portion 32 fixed to the upper cover 13, and the condenser portion 31 is formed of the metal. When inserted into the insertion hole 21 of the electrode body 20, the outer circumferential surface of the condenser portion 31 is fixed to the insertion hole 21 in close contact. Therefore, not only the electrical conductivity between the metal electrode body 20 and the negative electrode terminal 30 can be improved, but the negative electrode terminal 30 is firmly fixed to the metal electrode body 20.

The cell body 10 is provided with an air supply port 13b through which air is supplied, an electrolyte supply port 13c through which an electrolyte is supplied, and an outlet 14a, and the air supply port 13b with an electrolyte supply. Since the air supply means 70 and the electrolyte supply means 60 are connected to the port 13c, respectively, by additionally supplying air and electrolyte as necessary, and discharging as much of the electrolyte as replenished through the outlet 14a, There is an advantage to improve the power generation efficiency by efficiently removing the magnesium hydroxide which is a by-product generated during power generation.

Particularly, since the air supplied through the air supply port 13b is provided inside the cell body 10, an extension tube 71 is further provided to discharge the air between the air electrode 40 and the metal electrode body 20. By improving the efficiency of supplying oxygen in the air to the electrolyte, there is an advantage that can promote the reduction action to improve the power generation efficiency.

In addition, the electrolytic solution supply port 13c and the discharge port 14a are provided with electronic control valves 13d and 14b, respectively, and a control unit for receiving a signal from the water level sensor 80 provided in the cell body 10. By using the 90, by controlling the electronic control valve (13d, 14b), there is an advantage that can prevent the electrolyte level in the cell body 10 is lowered.

In addition, a plurality of vent holes 41a are formed in the carbon sheet 31 of the air electrode 40 so that oxygen is directly supplied to the electrolyte solution inside the cell body 10 through the vent holes 41a. In addition to smoothly supplying oxygen, a large diameter portion 41b is formed outside the vent hole 41a, and the vent hole 41a is blocked by the metal mesh 42 of the air electrode 40. There is an advantage that can be prevented.

In the present exemplary embodiment, an opening 12a is formed in the body main body 12 so that the periphery of the air electrode 40 is tightly fixed to the opening 12a. It is also possible to form a plurality of through-holes (12), so that the air electrode 40 wraps around the outer periphery of the body body (12).

1 is an exploded perspective view showing a conventional metal fuel cell,

2 is a perspective view showing a metal fuel cell according to the present invention;

3 is an exploded perspective view showing a metal fuel cell according to the present invention;

Figure 4 is a side cross-sectional view showing a metal fuel cell according to the present invention,

5 is a plan view showing a condenser part of a metal fuel cell according to the present invention;

6 is a side sectional view showing an air electrode of a metal fuel cell according to the present invention.

Claims (5)

A cell body 10 into which an electrolyte solution is injected; A metal electrode body 20 installed inside the cell body 10; A negative electrode terminal 30 connected to the metal electrode body 20; An air electrode 40 installed in the cell body 10 so as to be spaced apart from the metal electrode body 20; In the metal fuel cell comprising a positive electrode terminal 50 connected to the air electrode 40, Insertion holes 21 are formed in the metal electrode body 20 in the longitudinal direction, and one end of the cathode terminal 30 is fixed to the insertion hole 21, and the other end is outside of the cell body 10. Metal fuel cell, characterized in that extended. The method of claim 1, wherein the negative electrode terminal 30 is formed of a conductor and a resilient metal plate in a cylindrical shape, a plurality of projections (31a) is formed on the outer peripheral surface of the insertion hole 21 of the metal electrode body 20 And a terminal part (32) inserted into and installed in the cell body (10) and connected to an end of the condenser part (31). According to claim 1, wherein the upper end of the cell body 10 is provided with an air supply port 13b for supplying air, an electrolyte supply port 13c for supplying an electrolyte solution, and a lower end of the cell body 10 An outlet 14a is formed, Metal fuel cell further comprises an electrolyte supply means (60) connected to the electrolyte supply port (13c), and an air supply means (70) connected to the air supply port (13b). The extension tube (71) of claim 3, wherein one end of the cell body (10) is connected to the air supply port (13b) and the other end extends between the air electrode (40) and the metal electrode body (20). Metal fuel cell, characterized in that it is further provided. 4. The electrolytic solution supply port 13c and the discharge port 14a are provided with electronic control valves 13d and 14b, respectively. Is provided in the cell body 10, the water level sensor 80 for detecting the level of the electrolyte in the cell body 10, and the electronic control valve (13d, 14b) in accordance with the signal of the water level sensor 80 Metal fuel cell, characterized in that further provided with a control unit for controlling the 90.

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